Optimization of Network Throughput of Joint Radar Communication System Using Stochastic Geometry

IF 1.3 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Frontiers in signal processing Pub Date : 2022-01-10 DOI:10.3389/frsip.2022.835743
S. S. Ram, Shubhi Singhal, Gourab Ghatak
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引用次数: 8

Abstract

Recently joint radar communication (JRC) systems have gained considerable interest for several applications such as vehicular communications, indoor localization and activity recognition, covert military communications, and satellite based remote sensing. In these frameworks, bistatic/passive radar deployments with directional beams explore the angular search space and identify mobile users/radar targets. Subsequently, directional communication links are established with these mobile users. Consequently, JRC parameters such as the time trade-off between the radar exploration and communication service tasks have direct implications on the network throughput. Using tools from stochastic geometry (SG), we derive several system design and planning insights for deploying such networks and demonstrate how efficient radar detection can augment the communication throughput in a JRC system. Specifically, we provide a generalized analytical framework to maximize the network throughput by optimizing JRC parameters such as the exploration/exploitation duty cycle, the radar bandwidth, the transmit power and the pulse repetition interval. The analysis is further extended to monostatic radar conditions, which is a special case in our framework. The theoretical results are experimentally validated through Monte Carlo simulations. Our analysis highlights that for a larger bistatic range, a lower operating bandwidth and a higher duty cycle must be employed to maximize the network throughput. Furthermore, we demonstrate how a reduced success in radar detection due to higher clutter density deteriorates the overall network throughput. Finally, we show a peak reliability of 70% of the JRC link metrics for a single bistatic transceiver configuration.
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基于随机几何的联合雷达通信系统网络吞吐量优化
最近,联合雷达通信(JRC)系统在一些应用中获得了相当大的兴趣,例如车辆通信、室内定位和活动识别、秘密军事通信和基于卫星的遥感。在这些框架中,双基地/无源雷达部署与定向波束探索角搜索空间和识别移动用户/雷达目标。随后,与这些移动用户建立定向通信链路。因此,雷达探测任务和通信服务任务之间的时间权衡等JRC参数直接影响网络吞吐量。利用随机几何(SG)的工具,我们得出了部署这种网络的几个系统设计和规划见解,并演示了有效的雷达探测如何增加JRC系统中的通信吞吐量。具体来说,我们提供了一个通用的分析框架,通过优化JRC参数(如勘探/开采占空比、雷达带宽、发射功率和脉冲重复间隔)来最大化网络吞吐量。分析进一步扩展到单站雷达条件,这是我们框架中的一个特殊情况。通过蒙特卡罗模拟实验验证了理论结果。我们的分析强调,对于更大的双基地范围,必须采用更低的工作带宽和更高的占空比来最大化网络吞吐量。此外,我们还演示了由于较高的杂波密度而降低的雷达探测成功率如何降低整体网络吞吐量。最后,我们展示了单个双站收发器配置的JRC链路指标的峰值可靠性为70%。
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